Active gels play an important role in biology and in inspiring biomimetic active materials, due to their ability to change shape, size, and create their own morphology. We study a particular class of active gels, generated by polymerizing actin in the presence of cross-linkers and clusters of myosin as molecular motors, which exhibit large contractions. The relevant mechanics for these highly swollen gels is the result of the interplay between activity and liquid flow: gel activity yields a structural reorganization of the gel network and produces a flow of liquid that eventually exits from the gel boundary. This dynamics inherits lengthscales that are typical of the liquid flow processes. The analyses we present provide insights into the contraction dynamics, and they focus on the effects of the geometry on both gel velocity and fluid flow.

Bernheim-Groswasser, A., Livne, G., Nardinocchi, P., Recrosi, F., Teresi, L. (2024). Interplay between activity, elasticity, and liquid transport in self-contractile biopolymer gels. PHYSICAL REVIEW. E, 109(1) [10.1103/physreve.109.014601].

Interplay between activity, elasticity, and liquid transport in self-contractile biopolymer gels

Nardinocchi, Paola;Recrosi, Filippo;Teresi, Luciano
2024-01-01

Abstract

Active gels play an important role in biology and in inspiring biomimetic active materials, due to their ability to change shape, size, and create their own morphology. We study a particular class of active gels, generated by polymerizing actin in the presence of cross-linkers and clusters of myosin as molecular motors, which exhibit large contractions. The relevant mechanics for these highly swollen gels is the result of the interplay between activity and liquid flow: gel activity yields a structural reorganization of the gel network and produces a flow of liquid that eventually exits from the gel boundary. This dynamics inherits lengthscales that are typical of the liquid flow processes. The analyses we present provide insights into the contraction dynamics, and they focus on the effects of the geometry on both gel velocity and fluid flow.
2024
Bernheim-Groswasser, A., Livne, G., Nardinocchi, P., Recrosi, F., Teresi, L. (2024). Interplay between activity, elasticity, and liquid transport in self-contractile biopolymer gels. PHYSICAL REVIEW. E, 109(1) [10.1103/physreve.109.014601].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11590/472729
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